Fuel cell technology for domestic built environment applications: State of-the-art review

Elmer, Theo; Worall, Mark; Wu, Shenyi; Riffat, Saffa

doi:10.1016/j.rser.2014.10.080

Cited by 257 publications

(111 citation statements)

References 63 publications

(81 reference statements)

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“…Other types of FCVs, such as forklifts [8][9][10] and buses [11][12][13], have also been commercialized. Regarding residential energy applications, micro fuel cell combined heat and power (FC-CHP) systems could decrease household energy use owing to their high gross energy efficiencies (the sum of power generation efficiency and heat production efficiency) [14]. Megawatt-class hydrogen energy systems have also been installed around the world in data centers, hotels and many other commercial facilities to combine distributed renewable energy resources-such as solar photovoltaics (PV) and wind turbines-and measures to ensure a stable energy supply-such as battery storage, and water electrolyzers, storage tanks and fuel cells for hydrogen production, storage and use, respectively [15][16][17][18].…”

Section: Introductionmentioning

confidence: 99%

Assessing Uncertainties of Well-To-Tank Greenhouse Gas Emissions from Hydrogen Supply Chains

Ozawa

Inoue²,

Kitagawa

et al. 2017

Sustainability

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Abstract:Hydrogen is a promising energy carrier in the clean energy systems currently being developed. However, its effectiveness in mitigating greenhouse gas (GHG) emissions requires conducting a lifecycle analysis of the process by which hydrogen is produced and supplied. This study focuses on the hydrogen for the transport sector, in particular renewable hydrogen that is produced from wind-or solar PV-powered electrolysis. A life cycle inventory analysis is conducted to evaluate the Well-to-Tank (WtT) GHG emissions from various renewable hydrogen supply chains. The stages of the supply chains include hydrogen being produced overseas, converted into a transportable hydrogen carrier (liquid hydrogen or methylcyclohexane), imported to Japan by sea, distributed to hydrogen filling stations, restored from the hydrogen carrier to hydrogen and filled into fuel cell vehicles. For comparison, an analysis is also carried out with hydrogen produced by steam reforming of natural gas. Foreground data related to the hydrogen supply chains are collected by literature surveys and the Japanese life cycle inventory database is used as the background data. The analysis results indicate that some of renewable hydrogen supply chains using liquid hydrogen exhibited significantly lower WtT GHG emissions than those of a supply chain of hydrogen produced by reforming of natural gas. A significant piece of the work is to consider the impacts of variations in the energy and material inputs by performing a probabilistic uncertainty analysis. This suggests that the production of renewable hydrogen, its liquefaction, the dehydrogenation of methylcyclohexane and the compression of hydrogen at the filling station are the GHG-intensive stages in the target supply chains.

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Section: Introductionmentioning

confidence: 99%

Assessing Uncertainties of Well-To-Tank Greenhouse Gas Emissions from Hydrogen Supply Chains

Ozawa

Inoue²,

Kitagawa

et al. 2017

Sustainability

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“…The process can be divided into three general stages: (i) H2 production by SRE with preheating (HE1) to ensure the reaction temperature; (ii) H2 purification by water condensation (CDS), CO elimination by carbon monoxide preferential oxidation (PROX) with preheating (HE2) to ensure the reaction temperature (150 °C [65]), and CH4 and CO2 adsorption (ADS) with activated carbon and precooling (HE3) to ensure the adsorption temperature (70 °C [66]); and (iii) energy generation in FC with preheating (HE4) to ensure the reaction temperature (150 °C [67]). The energy divisor (ED) indicates that the FC produces both electrical (40%) and heat (60%) energy [68]. CO2 and CH4 adsorption (ADS) with activated carbon was selected among other methods like adsorption with oxides [69,70], because the first ensures simultaneously removal of CO2 and CH4 in post-reforming streams, requires less power consumption, and minimizes H2 losses [66].…”

Section: Energy Analysis From Rsm and Aspen Plus Integrationmentioning

confidence: 99%

Response Surface Methodology and Aspen Plus Integration for the Simulation of the Catalytic Steam Reforming of Ethanol

2017

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Abstract:The steam reforming of ethanol (SRE) on a bimetallic RhPt/CeO 2 catalyst was evaluated by the integration of Response Surface Methodology (RSM) and Aspen Plus (version 9.0, Aspen Tech, Burlington, MA, USA, 2016). First, the effect of the Rh-Pt weight ratio (1:0, 3:1, 1:1, 1:3, and 0:1) on the performance of SRE on RhPt/CeO 2 was assessed between 400 to 700 • C with a stoichiometric steam/ethanol molar ratio of 3. RSM enabled modeling of the system and identification of a maximum of 4.2 mol H 2 /mol EtOH (700 • C) with the Rh 0.4 Pt 0.4 /CeO 2 catalyst. The mathematical models were integrated into Aspen Plus through Excel in order to simulate a process involving SRE, H 2 purification, and electricity production in a fuel cell (FC). An energy sensitivity analysis of the process was performed in Aspen Plus, and the information obtained was used to generate new response surfaces. The response surfaces demonstrated that an increase in H 2 production requires more energy consumption in the steam reforming of ethanol. However, increasing H 2 production rebounds in more energy production in the fuel cell, which increases the overall efficiency of the system. The minimum H 2 yield needed to make the system energetically sustainable was identified as 1.2 mol H 2 /mol EtOH. According to the results of the integration of RSM models into Aspen Plus, the system using Rh 0.4 Pt 0.4 /CeO 2 can produce a maximum net energy of 742 kJ/mol H 2 , of which 40% could be converted into electricity in the FC (297 kJ/mol H 2 produced). The remaining energy can be recovered as heat.

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“…The development of a network of hydrogen filling stations realized with small-scale fuel processor units fed with hydrocarbon fuels has been conceived as a strategy to take advantage of the existing fuel infrastructure and favor a smooth transition from a fossil-based to a future renewable-based hydrogen economy [1][2][3][4][5]. In particular, small scale fuel processors have been studied for the auxiliary power units (APUs) which supply on-board energy for electrical uses other the vehicle motion, and for micro-combined heat and power units (micro-CHPs), the extension of the concept of cogeneration to small-scale applications [6,7]. Indeed, the penetration of advanced and efficient energy systems, based on fuel cells, was shown to have the potential for substantially contributing to the decarbonization of the energy system [8], in line with the EU Energy Roadmap target for 2050 [9].…”

Section: Introductionmentioning

confidence: 99%

“…Indeed, micro-CHP systems may fit well with the energy demand of buildings, and the application of micro-CHP to residential heat and power supply has grown among stakeholders, including energy companies, gas distributors, independent power producers and end users [7,11].…”

Section: Introductionmentioning

confidence: 99%

“…project funded by the Industria 2015 program. Indeed, micro-CHP systems may fit well with the energy demand of buildings, and the application of micro-CHP to residential heat and power supply has grown among stakeholders, including energy companies, gas distributors, independent power producers and end users [7,11]. A key issue related to micro-CHP systems is the reliability; the commercialization requires on one side, high efficiency and low environmental impact, and on the other side, stable, robust and easy-to-handle operability.…”

Section: Introductionmentioning

confidence: 99%

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Development of a Catalytic Fuel Processor for a 10 kW Combined Heat and Power System: Experimental and Modeling Analysis of the Steam Reforming Unit

et al. 2018

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Abstract:In this work, we address the development of a combined heat and power unit for residential applications, fed by natural gas, air and H 2 O; focus is on the design of the first catalytic stage of the fuel processor, that is the steam reforming unit. A commercial catalyst was tested at the laboratory scale, under kinetically controlled conditions in order to derive information on the reaction kinetics and support the basic engineering of the full scale reactor. Analogous tests after long term steam reforming ageing were then performed to quantify the evolution of the catalyst activity under real operating conditions and estimate a lumped deactivation factor. A modelling analysis was performed to predict the expected performance of the fuel processor at varying input parameters and catalyst activity profiles. It was verified that at a space velocity below 5000 Nl/kg cat /h, the reactor output is fully controlled by the thermodynamics at 650 • C, which guarantees the best operability and efficiency of the whole fuel processor.

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Fuel cell technology for domestic built environment applications: State of-the-art review

Cited by 257 publications

References 63 publications

Assessing Uncertainties of Well-To-Tank Greenhouse Gas Emissions from Hydrogen Supply Chains

Assessing Uncertainties of Well-To-Tank Greenhouse Gas Emissions from Hydrogen Supply Chains

Response Surface Methodology and Aspen Plus Integration for the Simulation of the Catalytic Steam Reforming of Ethanol

Development of a Catalytic Fuel Processor for a 10 kW Combined Heat and Power System: Experimental and Modeling Analysis of the Steam Reforming Unit

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